Headset with auxiliary input(s) for cell phone and/or other devices

ABSTRACT

An active-noise-reduction (ANR) headset includes at least one auxiliary connection to an output of at least one device, such as a personal communications, computing, and/or entertainment device. An exemplary headset also includes a primary connection to an aircraft two-way radio or public-address system and circuitry for automatically suppressing or muting the volume of an auxiliary input signal relative to that of a primary input signal. Other exemplary features include a headset power supply, a microphone, a microphone preamplifier, and a device-detection circuit. The device-detection circuit selectively couples the power supply to the microphone preamplifier, enabling it to provide audio signals to the microphone input of the auxiliary device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.13/018,910 filed Feb. 1, 2011, which is a continuation of U.S.application Ser. No. 11/735,704 filed Apr. 16, 2007, now U.S. Pat. No.7,907,721, which is a continuation of U.S. patent application Ser. No.10/624,906, filed Jul. 22, 2003, now U.S. Pat. No. 7,215,766, whichclaims priority under 35 U.S.C. 119(e) to co-pending and co-owned U.S.provisional application 60/397,888, filed Jul. 22, 2002, whichapplications are incorporated herein by reference.

TECHNICAL FIELD

The present invention concerns headphones or headsets and relatedcircuits and methods.

BACKGROUND

Headsets are used in a variety of applications to facilitate one- ortwo-way audio communications between users and/or devices. For example,many aircraft pilots wear headsets to enable them to communicate viatwo-way radio with other aircraft and air-traffic controllers as well asvia a public-address system with passengers. Additionally, some headsetsare worn to facilitate hands-free usage of mobile telephones, whileothers facilitate private listening to devices, such as computers,stereos, disk players, etc.

One problem that the present inventor recognized is that conventionalheadsets lack means for successfully integrating more than one audiosource, despite their proximity to multiple sources of audio signals.Accordingly, there is a need for headsets that facilitate use of morethan one signal source.

SUMMARY

To address this and/or other needs, the present inventor devised one ormore devices, circuits, and methods related to simultaneous connectionof at least two audio input signals to a headset. For example, in oneembodiment, an active-noise-reduction (ANR) headset includes at leastone auxiliary port for connection to an output of at least one device,such as a personal communications, computing, and/or entertainmentdevice. This exemplary headset also includes a primary port forconnection to a two-radio or public-address system and circuitry forautomatically suppressing or muting the volume of an auxiliary inputsignal relative to that of a primary input signal.

Other exemplary features include a headset power supply, a microphone, amicrophone preamplifier, and a device-detection circuit. Thedevice-detection circuit detects connection of the auxiliary port to amicrophone input and couples the power supply to the microphonepreamplifier, enabling it to provide audio signals to the microphoneinput.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an exemplary system 100 corresponding toone or more embodiments of the present invention.

FIG. 2 is a flow chart of an exemplary method of operating one or moreportions of system 100, which corresponds to one or more embodiments ofthe present invention.

FIG. 3 is an electrical schematic of one or more exemplary circuits insystem 100, each corresponding to one or more embodiments of the presentinvention.

DETAILED DESCRIPTION

The following detailed description, which references and incorporatesthe attached Figures, describes and illustrates one or more specificembodiments of the invention. These embodiments, offered not to limitbut only to exemplify and teach, are shown and described in sufficientdetail to enable those skilled in the art to implement or practice theinvention. Thus, where appropriate to avoid obscuring the invention, thedescription may omit certain information known to those of skill in theart.

FIG. 1 shows an exemplary system 100 incorporating teachings of thepresent invention. Specifically, system 100 includes a primary audiocommunication device 110, a secondary audio communications device 120,and an automatic-noise-reduction (ANR) headset 130.

Primary communications device 110 includes, among other items not shown,a headphone output jack 112 and a microphone jack 114 coupled tointernal circuitry not shown. In the exemplary embodiment, device 110takes the form of a two-way aircraft radio, with headphone jack 112being a 0.250-inch female stereo plug connector and microphone jack 114being a 0.206-inch, female stereo plug connector. In some embodiments,device 110 includes a public-address or intercom capability.

Secondary communications device (or system) 120 includes, among otheritems (not shown), an audio output jack 122 and an external microphonejack 124. In the exemplary embodiment, communications device 120 takesthe form of a cellular telephone, with output jack 122 and microphonejack 124 coupled to interface circuitry (not shown) which supports useof a conventional hands-free mobile-phone headset, which includes amicrophone and an ear-piece (or headphones). (Hands-free headsetstypically include an unbuffered electret microphone that is powered byinterface circuitry (not shown) in the cell phone or other typesecondary device. In the exemplary embodiment, this interface circuitryis not suitable for boom microphones in aviation headsets.) In someother embodiments, device 120 takes the form of a two-way radio, laptopcomputer, or other audio source or audio output device, such as a musicor video player or other personal listening device. In still otherembodiments, device 120 includes or is coupled to an input/output portof a larger multiport distribution network that distributes audiosignals, for example, throughout an airliner.

ANR headset 130 includes, among other things, an earpiece 132, a boommicrophone 134, and a controller 136. Earpieces 132, which each take theexemplary form of a circumaural earcup in this embodiment, fit over arespective ear of a user (not shown). However, in other embodiments, theearpiece takes the form of superaural, in-the-ear, or behind-the-eardevices. Specifically, earpiece 132 includes ANR control circuitry 1321,an ANR microphone 1322, an ANR speaker 1323, and a non-ANR speaker 1324.

Boom microphone 134 includes a boom 1341 which extends from one ofearpieces 132, and a microphone 1342 positioned at an end of the boom.Other embodiments use other forms of microphones. Earpiece 132 and boommicrophone 134 are both coupled to controller 136.

Controller 136 includes secondary-device detector 1361, a boommicrophone preamplifier 1362, a comm-priority module 1363, a battery box1364, and user controls 1365. In the exemplary embodiment, thecontroller is provided as a box or module separate from the earpieces;however, in some embodiments, all, or one, or portions of the controllerare incorporated into one or more of the earpieces. For example, someembodiments place one or more of the controller input jacks directly onone of the earpieces.

Secondary-device detector 1361 is coupled to microphone jack 124 ofsecondary communications device 120, microphone preamplifier 1362, andbattery box 1364. Microphone preamplifier 1362, in the exemplaryembodiment, is designed to operate using a 5-10 VDC voltage source and a600-2000 ohm resistor. Comm-priority module 1363 is coupled to headphonejack 122 of primary communications device 110 and to audio output jack122 of the secondary communication device. Manual controls 1365 includeon-off switch, left-right volume controls, stereo-mono switch,mode-programming switches, and bass and treble controls (all not shownseparately).

In general operation, secondary device detector 1361, which includes anaudio input jack coupled to microphone jack 124 of secondarycommunications device 120, senses or detects connection or activation ofdevice 120 to headset 130 and in response couples power derived frombattery box 1364 to boom microphone preamplifier 1362. Comm-prioritymodule 1363, which is coupled to the headphone jack of the primarycommunications device and to an audio output jack of the secondarycommunication device, provides an automatic muting or attenuationfunction that reduces the volume or amplitude of an audio or electricalsignal derived from the secondary communication device relative to thevolume or amplitude of an audio or electrical signal derived from theprimary communications device. Detector 1361 also senses decoupling ordeactivation of device 120 and in turn decouples battery box 1364 fromboom microphone preamplifier 1362.

More particularly, FIG. 2 shows a flow chart 200 of one or moreexemplary methods of operating system 100, particularly in relation tocontrol module 136. Flow chart 200 includes process blocks 210-280,which are arranged and described serially for clarity. However, two ormore of the blocks, in whole or in part, can be executed in parallel.Additionally, some embodiments may alter the process sequence byomitting or adding one or more blocks or provide different functionalpartitions to achieve analogous results. Moreover, still otherembodiments implement one or more of the blocks using a processor orprogrammable logic device and an electronic, magnetic, or opticalstorage medium bearing machine-executable instructions for execution orfacilitating execution of one or more portions of the exemplary method.Thus, the exemplary process flow applies to software, hardware,firmware, and other implementations beyond those exemplified here.

At block 210, exemplary execution begins with determining whether asecondary device, such as secondary communications device 120, iscoupled to headset 130, or more precisely control module 136. In theexemplary embodiment, this entails using detector 1361 to detect orsense a preamplifier bias signal from secondary communications device120. In some embodiments, the preamplifier bias signal is a 2.5VDCsignal, which is generally incompatible with the bias signal used inmost aviation-grade ANR headsets. Other embodiments may use the state ofa switch to determine connection of a secondary device. If thedetermination is that a secondary device is coupled to the headset,execution advances to block 220.

In block 220, detector 1361 couples power derived from battery box 1364to microphone preamplifier 1362, thereby enabling the headset toself-power its boom microphone rather than relying on power from theprimary communications device. This self-powering feature allows one touse the headset with the secondary communications device independent ofany connection to the primary communications device. One benefit of thisfeature is that it allows the secondary device to be used in a noisyenvironment with no other electronics or power beyond the headsetitself. Execution of the exemplary method continues at block 230.

Block 230 entails headset 130 receiving audio signals from one or theother or both of the primary and the secondary communications devices110 and 120. In the exemplary embodiment, these audio signals arereceived at comm-priority module 1363 via headphone jack 112 and/oraudio output 122. Execution then proceeds to block 240.

Block 240 entails determining whether to alter the relative amplitude ofthe primary and secondary audio signals. In the exemplary embodiment,this entails comparing the primary audio signal (more precisely thevoltage at headphone jack 112) to a threshold voltage. If the comparisonindicates that the primary audio signal is greater than the thresholdvoltage, execution advances to block 250; otherwise execution branchesto block 260.

Block 250 entails altering the relative amplitude of the primary andsecondary audio signals. In the exemplary embodiment, this alterationentails reducing the amplitude (or volume) of the secondary audio signalrelative to that of the primary audio signal. Some embodiments mayincrease the amplitude or volume of the primary audio signal to begreater than that of secondary audio signal. Some embodiments mayadditionally output a notification signal, such as high-pitched tone orbeep, to indicate presence of a primary audio signal in excess of thethreshold.

Block 260 entails mixing the primary and secondary audio signals. In theexemplary embodiment, this mixing entails mixing the primary audiosignal, or more precisely any voltage present on headphone jack 112 withthe reduced or unreduced secondary audio signal.

Block 270 entails outputting the mixed primary and secondary audiosignals to one or both of earpieces 132. In the exemplary embodiment,the mixed signals are output to speaker 1324 and to ANR circuitry 1321.Some embodiments, however, may omit or bypass the ANR circuitry.Execution then returns back to block 210.

Block 210 determines whether there is still a secondary device coupledto the headset. If the determination is that a device is still coupledto the headset, execution continues to block 220, as previouslydescribed. However, if the determination is that there is no secondarydevice (or that the secondary device has been deactivated, for example,as evidenced by failure to receive a microphone bias voltage from thedevice), then execution advances to block 280, which entails decouplingof the headset battery from the boom microphone preamplifier to conservebattery power.

FIG. 3 shows circuitry 300, which includes a detector circuit 310 thatrepresents an exemplary implementation of secondary-device detector 1361and a comm-priority circuit 320 that represents an exemplaryimplementation of comm-priority module 1363. In the figure, incomingsignals from the secondary device are received at secondary inputs Aux_Rand Aux_L, and incoming signals from the primary device are received atCOM_AUD TIP and COM_AUD GND. Battery terminals (shown in the lowerleft-hand corner) are labeled Bat+ and Bat−.

Detector circuit 310 detects the presence of an external bias signal atan audio input jack (denoted cell_mic in the figure) via a transistorQ6, which turns on the current source comprising a transistor Q10.Activation of the current source provides a bias current for the boommicrophone preamplifier. The current source has a compliance of over10VDC for undistorted communications at high-sound pressures. Notably,this implementation does not interfere with normal operation of the boommicrophone preamplifier, if it is connected to a radio or intercom biascircuit because it is a current source realizing a high Thevininequivalent impedance. Although not preferred, some embodiments may use asource with a low Thevinin equivalent impedance.

Comm-priority circuit 320 treats the Com_L input as the primary input tothe headset and compares this signal to a threshold voltage viacomparator circuitry that includes operational amplifier U1B. If thesignal at the Com_L input exceeds the trigger threshold (set byresistors R1 and R2, voltage V+, and processor output pin 11), then theoutput of operational amplifier U1B output goes high, saturatingtransistor Q8 and causing this transistor to rapidly discharge capacitorC1. In response to this discharge, operational amplifier U1C produces alow voltage at its output, which is coupled to a pulse-width-modulation(PWM) circuit comprising oscillator U4 and PWM comparator U3.

In turn, the PWM circuit reduces the duty cycle of its output signal.This output signals controls analog switch U11 (4053), which is part ofa chopping circuit, causing it to attenuate the auxiliary inputs Aux_Land Aux_R. U1A and U1D denote summing amplifiers that sum or mix theprimary and secondary inputs, and also provide a reconstruction filterfor the chopped signal. The outputs of summing amplifiers U1A and U1Dare then passed up to the earpieces for transduction into acousticsignals.

When the primary audio input stops exceeding the trigger threshold,capacitor C1 slowly starts to charge up via resistor R3, thus increasingthe duty cycle of the signal output from the PWM circuit and the gainlevel of the secondary audio input. The exemplary embodiment increasesthis gain linearly until it reaches its original level. (Non-linearrestoration of the secondary signal is also feasible.) Microprocessor U5is programmable via control inputs CONTROL1 and CONTROL2 to disablecommunications priority by setting processor output pin 11 to a highlogic state and thereby moving the trigger threshold for initiatingattenuation of the secondary input to a high value.

Other implementations could assign priority to the secondary inputs orallow the user to select which inputs have priority. The comm-priorityfunctionality is selectable and controlled through microprocessor U5using a combination of pushes of a button on a separate control module,such as module 136. Other embodiments place this control with controlson one or more of the earcups, the bridge between the earcups, or otherconvenient location.

CONCLUSION

The embodiments described above are intended only to illustrate andteach one or more ways of practicing or implementing the presentinvention, not to restrict its breadth or scope. The actual scope of theinvention, which encompasses all ways of practicing or implementing theconcepts of the invention, is defined by the following claims and theirequivalents.

What is claimed is:
 1. An automatic noise reduction (ANR) headset orheadset assembly for use with an aircraft two-way radio and a mobiletelephone, comprising: a pair of circumaural earcups connected by aheadpiece; a speaker associated with at least one earcup; an ANRmicrophone associated with at least one earcup; a boom microphoneextending from one of the earcups and coupled to a preamplifier; abattery connector for connecting a first power source having a firstvoltage level; a two-way aircraft radio input for connecting a secondpower source having a second voltage level different from the firstvoltage level; and control circuitry coupled to the speaker, the ANRmicrophone, the preamplifier, the battery connector, and the two-wayaircraft radio input, wherein the control circuitry generates signalsfor the speaker to provide automatic noise reduction based on signalsfrom the ANR microphone and selectively couples the preamplifier toreceive power from the first power source or the second power source toenable use of the boom microphone with the mobile telephone, and whereinthe control circuitry comprises a communications priority module thatreduces amplitude of an audio signal from an auxiliary device coupled tothe headset or headset assembly relative to amplitude of an audio signalfrom the aircraft two-way radio.
 2. The headset or headset assembly ofclaim 1 wherein the control circuitry mixes signals from the mobiletelephone and the aircraft two-way radio input.
 3. The headset orheadset assembly of claim 2 wherein the control circuitry modifies gainof the signal from the mobile telephone.
 4. The headset or headsetassembly of claim 2 wherein the control circuitry increases gain of asignal from the aircraft two-way radio.
 5. The headset or headsetassembly of claim 2 wherein the control circuitry selectively mutes thesignal from the mobile telephone.
 6. The headset or headset assembly ofclaim 1 wherein the communications priority module attenuates at leastone of the signals from the mobile telephone and the two-way aircraftradio input.
 7. The headset or headset assembly of claim 1 wherein thecontrol circuitry comprises: a first circuit coupled to the speaker andthe ANR microphone that generates signals for the speaker based onsignals received from the ANR microphone; and a second circuit coupledto the preamplifier that selectively provides an associated operatingvoltage to the preamplifier from a battery associated with the batteryconnector when the headset is coupled to the mobile telephone to enableuse of the boom microphone with the mobile telephone.
 8. The headset orheadset assembly of claim 7 wherein the boom microphone provides anaudio input signal to the mobile telephone.
 9. The headset or headsetassembly of claim 1 wherein the control circuitry comprises: a devicedetector that detects connection of the mobile telephone and selectivelycouples power from the first power source to the preamplifier inresponse.
 10. A method for operating an automatic noise reduction (ANR)headset or headset assembly with an aircraft two-way radio and a mobiletelephone, the headset or headset assembly including a pair ofcircumaural earcups connected by a headpiece, a speaker associated withat least one earcup, an ANR microphone associated with at least oneearcup, a boom microphone extending from one of the earcups and coupledto a preamplifier, and a battery box, the method comprising: generatingsignals for the speaker to provide automatic noise reduction based onsignals from the ANR microphone; coupling power derived from theaircraft two-way radio to the preamplifier coupled to the boommicrophone for operation of the boom microphone with the aircrafttwo-way radio; coupling power derived from the battery box to thepreamplifier coupled to the boom microphone for operation of the boommicrophone with the mobile telephone; and muting audio from an auxiliarydevice coupled to the headset or headset assembly relative to amplitudeof an audio signal from the aircraft two-way radio.
 11. The method ofclaim 10 further comprising decoupling power derived from the batterybox when no mobile telephone signal is detected.
 12. The method of claim10 further comprising mixing audio signals from the aircraft two-wayradio and the mobile telephone.
 13. An automatic noise reduction (ANR)or headset assembly for use with an aircraft communications device and amobile telephone, comprising: a pair of earpieces connected by aheadpiece; a speaker associated with at least one earpiece; an ANRmicrophone; a boom microphone extending from one of the earpieces; afirst input for receiving first audio signals from the communicationsdevice to couple the communications device to the headset or headsetassembly; a second input for receiving second audio signals from anaudio source, distinct from the communications device; a microphonepreamplifier coupled to the boom microphone; a battery terminal; and acircuit for selectively coupling and decoupling the microphonepreamplifier to the battery terminal, wherein the microphonepreamplifier is coupled to the battery terminal when the communicationsdevice is decoupled or deactivated, and for selectively varyingamplitude of an audio signal from the audio source coupled to theheadset or headset assembly relative to amplitude of an audio signalfrom the communications device.
 14. The headset or headset assembly ofclaim 13, further comprising a circuit for changing relative amplitudeof the received first and second audio signals.
 15. The headset orheadset assembly of claim 13, wherein the communications device is atwo-way radio or intercom, and the audio source is an entertainmentdevice.
 16. The headset or headset assembly of claim 1 wherein thecontrol circuitry decouples the preamplifier from the battery connectorwhen the mobile telephone is decoupled or deactivated.
 17. The headsetor headset assembly of claim 1 wherein the control circuitry couples thepreamplifier to receive power from the battery connector in response toa signal from the mobile telephone and decouples the preamplifier whenthe signal from the mobile telephone is not detected.
 18. The headset orheadset assembly of claim 1 wherein the control circuitry selectivelycouples and decouples the preamplifier to receive power from theaircraft two-way radio input or the battery connector based on signalsfrom the two-way aircraft radio input and the mobile telephone.
 19. Theheadset or headset assembly of claim 1 wherein the mobile telephone isconnected via an associated auxiliary input jack of the headset orheadset assembly.
 20. The headset or headset assembly of claim 1 whereinthe control circuitry selectively couples the preamplifier to receivepower from the battery connector when power from the two-way aircraftradio input is unavailable.
 21. The method of claim 10 wherein theaircraft two-way radio provides power having a first voltage and thebattery box provides power having a second voltage different from thefirst voltage.
 22. The method of claim 11, wherein coupling powerderived from the battery box comprises coupling power derived from thebattery box in response to detection of the mobile telephone signal.